DNA sequences, recombinant DNA molecules and processes for producing the A and B subunits of cholera toxin and preparations containing so-obtained subunit or subunits

ABSTRACT

DNA sequences and recombinant DNA molecules comprising at least a portion coding for all or part of subunits A and/or B of cholera toxin are prepared by enzymatic digestion of DNA of V. cholerae strains, isolating specific fragments and inserting them in appropriate vectors and subunits A and/or B of cholera toxin are prepared by culture of microorganisms containing said modified vectors.

The present invention relates to DNA sequences recombinant DNA molecules and processes for producing the A and B subunits of Cholera toxin and preparations containing so-obtained subunit or subunits.

It is known that the holotoxin produced by certain strains of Vibrio cholerae is composed of two protein subunits which are known as A and B subunits.

The A subunit (CTA) is responsible for epithelial cell penetration and the enzymatic effect leading to net loss of fluid into the gut lumen, whereas the B subunit (CTB) binds the holotoxin to monosialosylganglioside G_(M1) receptor sites on the cell wall, possesses no toxic activity and is highly immunogenic.

Among the Vibrio cholerae strains producing the holotoxin are for instance the well known Vibrio cholerae biotype El Tor serotype INABA strains and, in Proc. Natl. Acad. Sci. USA 76, 2052-2056, 1979, T. HONDA and R. A. FINKELSTEIN described a Vibrio cholerae mutant which produces the B subunit but no detectable A subunit of the cholera toxin.

Existing cholera vaccines containing either lipopolysaccharides extracted from vibrios or dense killed vibrio suspensions can, after repeated injection, confer limited protection to heavily exposed contacts but they are not effective as an epidemic control measure. It has also been demonstrated in human volunteers that, after recovery from cholera, antibodies to the homologous organism and a high degree of resistance to it but not to heterologous strains are present.

Considering that cholera holotoxin is highly antigenic and that there is only one immunologic type, it has been suggested that an effective antitoxic immunity should protect against the various serotypes and biotypes of V. cholera.

With that view, the B subunit appears to be a desirable vaccine component to induce protective antibodies either by oral or parenteral administration and different authors have proposed cholera vaccines based on the B subunit toxin or, less preferably, toxoids (J. HOLMGREN et al. in Nature 269, 602-603, 1977; HONDA and R. A. FINKELSTEIN in op. cit. and J. HOLMGREN in Nature 292, 413-417, 1981).

Prior to this invention, it was also known that the holotoxin is specified by a chromosomal gene (ctx) and S. L. MOSELEY and S. FALKOW (J. Bact. 144, 444-446, 1980) have shown that DNA fragments representing the two cistrons of the related heat labile enterotoxin gene (elt) of E. coli can be used as probes in DNA/DNA hybridization experiments to detect specific ctx gene fragments of V. cholerae total DNA digested with various restriction endonucleases.

We have found and this is an object of the present invention that digestion of DNA of a toxigenic Vibrio cholerae strain producing the holotoxin (which strain is herein exemplified by a Vibrio cholerae El Tor INABA strain which has been deposited with the American Type Culture Collection, Rockville, Md, U.S.A. under accession number ATCC 39050) with ClaI endonuclease releases two distinct bands of DNA which hybridize respectively and exclusively to the eltB and eltA probes and therefore contain the related ctxB and ctxA cistrons.

According to the invention, the fragments containing either the ctxA or ctxB gene and obtained by ClaI endonuclease treatment as indicated hereinabove are then inserted either separately or sequentially into an appropriate vector which has been previously cleaved by ClaI endonuclease, to constitute cloning vehicles in nost microorganisms such as for instance an E. coli K12 strain or a non toxigenic V. cholerae strain. The finally obtained strains are then used for the production of either the A subunit or the B subunit or both A and B subunits of the cholera toxin or genetically modified derivatives thereof.

More particularly and as exemplified hereafter a 1.0×10⁶ a ClaI generated DNA fragment containing the major part of the ctxA gene has been cloned on plasmid pBR322, as shown in FIG. 1 which represents the restriction map of the 1.0×10⁶ daltons insert on the so-obtained recombinant plasmid pRIT10841.

a 2.45×10⁶ d ClaI generated DNA fragment containing the ctxB gene has been cloned on plasmid pBR322, as shown in FIG. 2 which represents the restriction map of the 2.45×10⁶ daltons insert on the so-obtained recombinant plasmid pRIT10810. fragments containing both ctxA and ctxB genes have been cloned on plasmid pBR327 as a 0.75×10⁶ daltons ClaI-BglII ctxB insert joined to the 1.0×10⁶ d ClaI ctxA insert, as shown in FIG. 3 which represents the restriction map of the inserts on the so-obtained recombinant plasmid pRIT10814.

Samples of an E. coli K12 strain have been transformed with the inclusion of the plasmids pRIT10841, pRIT10810 and pRIT10814, respectively and cultures of these transformed strains have been deposited with the American Type Culture Collection, Rockville, Md., U.S.A. under the respective accession number ATCC 39053, ATCC 39051 and ATCC 39052.

Furthermore a 5.1×10⁶ d PstI DNA fragment has been cloned from ATCC 39050 onto the plasmid vector pBR322 to form the recombinant plasmid pRIT10824. This plasmid has the same number and disposition of restriction sites in and around the ctx coding sequences as the aforementioned pRIT10814.

It is obvious that the above process is not restricted to the exemplified ATCC 39050 strain and that when using as starting material a V. cholerae strain producing either the A subunit only or the B subunit only, bands of DNA containing either the ctxA cistron or the ctxB cistron will be obtained, respectively.

If proceeding with cloning of ClaI digested DNA of the classical Vibrio cholerae strain 569B (ATCC 25870) which contains two copies of the toxin gene, fragments of 1.25×10⁶ d would be chosen as representing the ctxA sequences and fragments of either 0.88×10⁶ d and/or 0.78×10⁶ d would be chosen as representing the ctxB sequences.

Either each of the A and B subunits or both together are valuable for the preparation of cholera vaccines for which the A subunit is necessarily used in the form of a toxoid and the B subunit is less preferably used in the form of a toxoid.

According to another embodiment of the present invention, the cloned DNA fragments are employed to generate toxoid forms of the A or B subunits by genetic manipulation in vivo or in vitro. Examples of this well known to those skilled in the art are the creation of deletions or insertions of nucleotide base pairs at specific restriction sites or directed site specific mutagenesis to change particular amino acids. Furthermore it is also practicable to create hybrid toxin molecules by in vitro genetic manipulation, for example by recombining the related neat labile enterotoxin gene of E. coli with the present cloned cholera toxin gene at their homologous XbaI restriction sites in such a fashion as to replace the cholera toxin gene promoter region, the leader or signal peptide and the first nine amino acids of the mature A subunit protein by the corresponding LT sequences Expression of such a hybrid toxin consisting mainly of cholera toxin sequences would thus be regulated by an E. Coli promoter region presenting advantages for synthesis of the toxin in E. coli cells.

Pharmaceutical formulations containing either the B subunit or a toxoid and valuable as vaccines to be administered by oral and/or parenteral routes are prepared according to any technique known in the art for such preparation, i.e. for instance either by addition of an antacid such as sodium bicarbonate or by enteric coating or microencapsulation of the active ingredient; the toxoid is also easily obtained from the toxin e.g. by treatment with formaldehyde or, preferably, glutaraldehyde.

The A and B subunits of the present invention are also valuable for the characterization of environmental strains of V. cholerae by their possible use as radio-labelled probes in DNA/DNA hybridization experiments to detect ctxA and/or ctxB genes fragments in unknown V. cholerae strains upon digestion of their total DNA with restriction endonucleases or by colony hybridizations.

The invention is illustrated by the following examples.

EXAMPLE 1 Preparation of DNA of V. cholerae ATCC 39050

V. cholerae ATCC 39050 is allowed to grow in syncase medium (FINKELSTEIN et al. J. Immunol. 96, 440-449, (1966) to reach stationary phase. The cells are then recovered by centrifugation, washed and resuspended in a buffer containing 0.05 M tromethamine, 0.1M NaCl, 0.25M edetic acid (EDTA), pH 8.0. Cells are lysed by the addition of sodium dodecyl sulfate (SDS) to 1% (w/v) final concentration and the mixture extracted twice (with equal volumes of buffer saturated phenol. The DNA is precipitated with two volumes of cold ethanol, recovered by spooling onto a glass rod and dissolved in 1×SSC (1×SSC is standard saline citrate, i.e.: 0.15 M NaCl, 0.015M trisodium citrate, pH 7.0).

Tromethamine buffer (pH 8.0) is added to 0.05M final concentration and the preparation incubated with bovine pancreatic ribonuclease (10 μg/ml final concentration) for 1 hour at 37°. The mixture is extracted twice with equal volumes of buffer saturated phenol, the DNA precipitated with ethanol, dissolved in 1×SSC and dialyzed against 1×SSC.

A sample of 6 μg of the obtained DNA is digested with 45.6 units of ClaI endonuclease for 3 hours at 37° C. in a total volume of 40 μl.

The ClaI digested Vibrio cholerae DNA is divided into two equal samples and electrophoresed in separate slots of a 1% agarose gel (the electrophoresis buffer is that described by HAYWARD G. S. and SMITH M. G., J. Mol. Biol. 63, 383, (1972) and contains 0.5 μg/ml ethidium bromide).

Samples of DNA of phage lambda sequentially digested with HindIII and EcoRI restriction endonucleases are run in other slots of the same gel to serve as molecular weight markers using the values given by CORY, S. and ADAMS, J. Cell 11, 795 (1977).

After electrophoresis the gel is illuminated with short wave ultraviolet light to visualize the DNA fragments and photographed to preserve a record of the relative migration of the phage lambda DNA bands. DNA fragments in the gel are then transferred and bound to a nitrocellulose filter by the technique of SOUTHERN E. M., J. Mol. Biol. 98, 503 (1975).

The filter is cut in two lengthwise so as to obtain samples of V. cholerae DNA digested with ClaI on each half of the filter.

EXAMPLE 2 Preparation of eltA and eltB gene specific DNA probes

pEWD299 plasmid DNA is prepared using CsCl density gradient centrifugation by the method described by KAHN M. et al., Methods in Enzymology, 68, 268, (1979) and the desired DNA fragments are separated and purified by digesting 50 to 100 μg of pEWD299 plasmid DNA with an excess of either the restriction endonucleases HincII (for eltA) or sequentially with restriction endonuclease HindIII and EcoRI (for eltB) followed by electrophoresis on 7.5% acrylamide gel. The construction and characterization of plasmid pEWD299 has been described by DALLAS W. and coll. in J. Bact. 139, 850 (1979).

That portion of the gel containing the desired fragment (the eltA gene fragment is a 1000 base pair DNA fragment and the eltB gene fragment is a 600 base pair DNA fragment) is excised with a scalpel, placed in a sac of dialysis membrane and the DNA eluted from the gel slice by electrophoresis. DNA eluted into the electrophoresis buffer within the sac is recovered and concentrated by ethanol precipitation. The DNA recovered is dissolved in 20 μl of 0.01 M-tromethamine buffer, pH 7.0.

The obtained eltA and eltB gene specific DNA fragments are those described by MOSELEY S. and FALKOW S., J. Bacteriol. 144, 444 (1980).

EXAMPLE 3 Labelling of DNA probe fragments by nick translation

Aliquots (0.5 μg) of the eltA and eltB DNA fragments purified as described in Example 2 are labelled in separate reaction mixtures with deoxycytidine 5'-triphosphate (α-³² P) by the method known as nick translation (RIGBY P. et al., J. Mol. Biol. 113, 237 (1977)) using the kit (NEK-004) and reaction conditions supplied by New England Nuclear (Dreieich, Fed. Rep. Germany).

The specific activities of the DNA fragments so labelled are: 2.3×10⁷ cpm per 0.5 μg DNA for the eltA DNA, and 3.14×10⁷ cpm per 0.5 μg DNA for the eltB DNA. The labelled DNA is then denaturated before use by heating at 100° C. for 10 to 15 minutes.

EXAMPLE 4 Hybridization of filter bound DNA with the eltA probe

One half of the nitrocellulose filter containing bound, denaturated V. cholerae DNA fragments prepared as described in Example 1 is incubated for 3 hours at 37° in a prehybridization solution containing 5×SSC, 1 mM EDTA pH 8.0, 0.1% w/v sodium dodecyl sulfate (SDS), 1% v/v of the solution described by DENHARDT D., Biochem. Biophys. Res. Comm. 23, 641 (1966) prepared as a 100 fold concentrated solution and 25% v/v desionised formamide. The filter is then placed in a hybridization solution of the same composition but containing in addition 25 μg per ml heat denatured salmon sperm DNA and the radioactive, denatured eltA probe of Example 3 diluted to give a final specific activity of 9×10⁵ cpm per ml. The filter is incubated in this solution for 36 hours at 37° and thereafter incubated twice for 25 minutes at 37° in solutions of the same compositions as used for hybridization but from which the radioactive probe DNA had been omitted. The filter is then rinsed twice for 25 minutes at room temperature in solutions of 0.2×SSC and air dried. The dried filter is exposed to X-ray film (Fuji Photo film Co. Ltd) for a time sufficient to darken areas of the film corresponding to those areas of the filter where radioactive probe DNA has hybridized to the bound denatured fragments of V. cholerae DNA.

Examination of X-ray films exposed to the filter incubated with the eltA probe shows that the eltA gene fragment hybridizes specifically and exclusively to a single band of ClaI digested total DNA of Vibrio cholerae ATCC 39050. This DNA fragment has an estimated molecular weight of 1.0×10⁶ daltons by comparison to the relative migration of lambda DNA fragments. The V. cholerae DNA sequence showing homology in these hybridization conditions to the eltA probe represents all or part of the ctxA cistron which specifies the structural gene sequence for the subunit A of cholera toxin.

EXAMPLE 5 Hybridization of filter bound DNA with the eltB probe

An identical procedure is followed to hybridize radioactive eltB probe DNA with the other half filter containing bound denatured V. cholerae DNA except that a formamide concentration of 20% v/v is used and the eltB probe DNA is diluted to give a specific activity of 1.2×10⁶ cpm per ml in the hybridization solution. The eltB probe hybridizes specifically and exclusively in the conditions described to a single band of ClaI digested V. cholerae ATCC 39050 DNA with an estimated molecular weight of 2.45×10⁶ daltons.

The V. cholerae DNA sequence showing homology in these hybridization conditions to the eltB probe represents all or part of the ctxB cistron which specifies the structural gene sequence for the subunit B of cholera toxin.

EXAMPLE 6 Enrichment of DNA fragments containing either ctxA or ctxB gene sequences from total DNA of V. cholerae

A 63 μg aliquot of total DNA as obtained in Example 1 is digested for 3 hours at 37° with 500 units of ClaI endonuclease in a total reaction volume of 400 μ. The digested DNA is electrophoreses on a 1% (w/v) agarose gel. A sample of DNA of phage lambda digested with EcoRI and HindIII endonucleases and a sample of DNA of pEWD020 (W. DALLAS et al., J. Bacteriol. 139, 850 (1979)) digested with BamHI and EcoRI endonucleases are run in separate slots of the same gel to serve as molecular weight markers. The positions of V. cholerae DNA fragments from the ClaI endonuclease digest corresponding to molecular weights of 2.45×10 d and 1.0×10⁶ d are estimated by reference to the molecular weight markers and five 1 mm slices are cut crosswise from the gel at and above and below each of these two points. The DNA in each gel slice is recovered by electroelution in a closed sac of dialysis membrane. The fluid is removed from each sac, filtered through an 0.45μ Millipore filter to remove agarose fragments and the DNA recovered by precipitation with an equal volume of isopropanol. The precipitate is dissolved in 0.01 M tromethamine buffer pH 7.0 and reprecipitated with 2 volumes of ethanol. The DNA obtained from each gel slice is finally dissolved in 20 μl of 0.01 M tromethamine, 0.001M EDTA buffer, pH 7.0.

One μl samples of each DNA preparation are assayed for their content of ctxA or ctxB gene sequences by the dot hybridization method described by KAFATOS F. et al. (Nucl. Acids Res. 7, 1541 (1979)) and using the hybridization conditions and radioactive eltA and eltB probe DNAs described in Examples 2 to 5.

Two DNA preparations corresponding to 1.0×10⁶ d DNA are found to hybridize more strongly with the eltA probe than the other three.

Similarly two DNA preparations of DNA of 2.45×10⁶ d hybridize more strongly with the eltB probe.

EXAMPLE 7 Cloning of DNA enriched for ctxB gene sequences

Aliquots (5 μg) of pBR322 plasmid DNA prepared by CsCl density gradient centrifugation are digested with 6.6 units of ClaI endonuclease for 2 hours at 37° in a reaction volume of 100 μl. To a 60 μl sample of this digest containing 3 μg of plasmid DNA are added 100 μl of glycine buffer (0.1M glycine, 1 mM MgCl₂ 6H₂ O, 0.1 mM ZnSO₄, 7 H₂ O, pH 10.5) and 0.3 units of calf intestine alkaline phosphatase. The mixture is incubated 30 minutes at 37°, extracted twice with an equal volume of phenol, extracted three times with ether and the DNA precipitated with ethanol. The pBR322 DNA is dissolved in 30 μl of 0.01 M tromethamine-HCl, 0.001M EDTA buffer pH 7.0.

Aliquots (10 μl) of each of the two DNA fractions obtained in Example 6 and showing the strongest hybridization signal to the eltB probe are mixed with 0.4 μg of the ClaI digested, alkaline phosphatase treated pBR322 DNA and the mixture brought to a final volume of 30 μl with tromethamine buffer, extracted with an equal volume of phenol, extracted three times with ether, precipitated with ethanol and the DNA is dissolved in 20 μl of 0.01 M tromethamine-HCl, 0.001M EDTA buffer pH 7.0.

The mixture of V. cholerae DNA fragments and pBR322 DNA is ligated by incubation with T4-DNA ligase. To 10 μl of DNA mixture is added 10 μl of a T4-DNA ligase cocktail to give a solution containing 20 mM tromethamine HCl, pH 7.6, 10 mM MgCl₂.6H₂ O, 10 mM dithiothreitol, 1.2 mM deoxyadenosine triphosphate, 50 μg per ml bovine serum albumin and 0.5 units of T4-DNA ligase (Boehringer Mannheim, Fed. Rep Germany).

The ligase containing mixture is incubated for 4 hours at 15° C. to obtain ligation of the V. cholerae DNA fragments to the ClaI digested pBR322 DNA and form recombinant molecules.

The total ligated DNA mixture (20 μl) is used to transform CaCl₂ treated competent cells of E. coli K12 strain MM294 (described by BACKMAN K. et al., Proc. Natl. Acad. Sci. U.S. 73, 4174 (1976)) prepared according to the procedure described by COHEN S. et al., Proc. Natl. Acad. Sci. U.S. 69, 2110 (1972). The transformed culture is spread on solid agar medium containing 200 μg per ml ampicillin to select for those cells which have taken up pBR322 plasmid DNA. Approximately 1000 ampicillin resistant colonies are recovered from the total transformed culture.

EXAMPLE 8 Screening of transformed colonies for ctxB gene sequences.

The ampicillin resistant transformed colonies obtained in Example 7 are screened for the presence of DNA sequences hybridizing to the eltB probe by the colony hybridization method described by GERGEN J. et al. Nucl. Acids Res. 7, 2115 (1979). Transformant colonies growing on the solid agar medium are transferred in fixed arrays to the surface of duplicate plates of ampicillin containing medium and the plates incubated at 37°. A square of sterile filter paper (Whatman 541) is placed on the surface of one plate of each pair and the bacterial growth stripped from the agar surface by removing the filter paper. By this procedure a replica is obtained on the filter paper of the colonies grown on the solid agar medium. The filter papers are dried for 15 minutes at 37° and processed as described by GERGEN J. et al. (loc. cit.) except that the ethanol wash is omitted.

The filter papers so treated are hybridized with the radioactive eltB probe DNA in exactly the same conditions and by the procedure described in Example 5 and exposed to X-ray film for varying periods of time.

Ten colonies are noted which are clearly darker than the rest and these are located and recovered from the duplicate agar plates. Of these 10 colonies showing a positive hybridization result, four are tetracycline sensitive, indicative of insertional inactivation of the tetracycline resistance gene on the pBR322 vector by a foreign DNA fragment.

Plasmid DNA is prepared from each of these four colonies by the procedure of BIRNBOIM H. and DOLY J. (Nucl. Acids Res. 7, 1513 (1979) and restriction analysis with ClaI endonuclease shows that in each preparation the pBR322 vector carries a DNA insert with a molecular weight of 2.45×10⁶ d. One so-isolated colony was characterized as being MM294 (pRIT10810) of which a culture has been deposited with the American Type Culture Collection under accession number ATCC 39051.

EXAMPLE 9 Characterization of ATCC 39051 strain

Plasmid DNA was prepared from ATCC 39051 strain by CsCl-ethidium bromide density gradient centrifugation and subjected to further restriction endonuclease analysis. The 2.45×10⁶ daltons ClaI DNA insert is characterized in having the restriction sites and orientation vis-a-vis the pBR322 vector DNA as shown in FIG. 1.

The strain was further characterized in producing a protein reacting with antibodies raised against pure cholera toxin in an enzyme linked immunosorbent assay described by SVENNERHOLM A. and HOLMGREN J. (Curr. Microbiol. 1, 19, 1978) and based on the binding of the B subunit protein of cholera toxin to GMl ganglioside receptors.

Extracts of broth grown cells of ATCC 39051 strain prepared by passage through a French pressure cell and clarified by centrifugation at 30,000×g for 30 minutes at 4° C. were found to be strongly positive for B subunit protein by this ELISA assay.

To further characterize the cloned insert, pRIT10810 DNA was digested sequentially with ClaI and HincII endonucleases and the 0.2×10⁶ fragment was purified by electrophoresis on an acrylamide gel and electroelution of the gel slice containing the fragment. 0.5 μg of this purified fragment was labelled with ³² P by nick translation as described in Example 3 to a specific activity of 1.96×10⁸ cpm per 0.5 μg for use as a probe. Total DNA of ATCC 39050 strain was digested with various endonucleases and samples electrophoresed on agarose gels, denatured and transferred to nitrocellulose filters. These filters were incubated with the radioactive, denatured ClaIHincII probe DNA in stringent conditions of DNA/DNA hybridization, omitting formamide from the hybridization, omitting formamide from the hybridization solutions and performing the incubation at 65° for 18 hours.

Examination of X-ray films exposed to the hybridized nitrocellulose filters showed that exactly the same bands of Vibrio DNA were revealed with the Vibrio ClaI-HincII probe as had been detected in Example 5 with the eltB probe in less stringent conditions. This results shows that the cloned DNA is of Vibrio cholerae origin.

EXAMPLE 10 Cloning of V. cholerae DNA enriched for ctxA gene sequences

Ten μg of each of the two ClaI digested DNA fractions (showing the strongest hybridization signal to the eltA probe), described in Example 7, are mixed with 0.4 μg of ClaI digested and alkaline phosphatase treated pBR322 DNA.

The DNA mixture is extracted with phenol, alcohol precipitated, dissolved and ligated with T4-DNA ligase exactly as described in Example 7 and used to transform CaCl₂ treated cells of strain E. coli K12, MM294. A total of about 4000 colonies are recovered by inoculating the transformed culture on ampicillin containing agar medium at 37°.

The ampicillin resistant colonies described above were screened for the presence of DNA sequences hybridizing to the eltA probe using the procedures and conditions described in Example 8. Two colonies were detected which gave a positive response with the eltA probe and which were tetracycline sensitive. Plasmid DNA was prepared from these two clones by the method of BIRNBOIM and DOLY (loc. cit.) and digestion with ClaI endonuclease released, in addition to the pBR322 vector fragment, a DNA fragment of 1.0×10⁶ d. The two colonies were characterized as being MM294 (pRIT10841) and MM294 (pRIT10851). A culture of MM294 (pRIT10841) has been deposited with the American Type Culture Collection under accession number ATCC 39053.

EXAMPLE 11 Characterization of ATCC 39053 strain

Plasmid DNA was prepared from ATCC 39053 strain by CsCl-ethidium bromide gradient centrifugation and subjected to further restriction endonuclease analysis. The 1.0×10⁶ daltons DNA insert is characterized in having the placement of the BstEII and XbaI restriction sites and orientation vis-a-vis the pBR322 vector DNA as is shown in FIG. 2. The ClaI insert DNA is further characterized in having no sites for EcoRI, BamHI, HindIII, PstI, SacI, PvuI, XhoI, AvaI, BglII, HpaI, SmaI, HincII, PvuII or Sall endonucleases.

Purified DNA of pRIT10841 was digested with ClaI endonuclease and the 1.0×10⁶ daltons fragment purified by agarose gel electrophoresis and electroelution. 0.5 μg of this DNA was labelled with ³² p by nick translation as described in Example 3 and used as a probe.

Total DNA of ATCC 39050 strain was digested with various restriction endonucleases and samples electrophoresed on agarose gels, denatured in situ and transferred to nitrocellulose filters. Incubation in stringent conditions of hybridization of the denatured ClaI probe DNA fragment to Vibrio DNA fixed to the filters showed that the probe detected exactly the same bands of Vibrio DNA as had been detected by the eltA probe in relaxed hybridization conditions.

This result shows that the cloned DNA is of Vibrio origin.

EXAMPLE 12 Construction of pRIT10812

A 25 μg aliquot of plasmid DNA of pRIT10810 prepared as described in Example 9 is digested sequentially with 55 units of ClaI endonuclease for 3 hours at 37° and 24 units of BglII endonuclease for 2 hours at 37°. The digested DNA is electrophoresed on a 1% agarose gel and the 0.75×10⁶ daltons ClaI-BglII DNA fragment containing the ctxB gene sequences is cut from the gel and the DNA recovered by electroelution.

Plasmid DNA (2.5 g) of pBR327 (SOBERON X. et al., Gene 9, 287, 1980) is sequentially digested with 11 units of ClaI endonuclease for 2.5 hours at 37° C. and with 8 units of BamHI endonuclease for 2 hours at 37°. The digested DNA is extracted twice with phenol, 3 times with ether, ethanol precipitated and dissolved in 0.01 M tromethamine buffer pH 7.0. A 0.4 μg aliquot of the purified ClaI-BglII ctxB DNA fragment is ligated with 0.2 μg of ClaI and BaMHI digested DNA of pBR327 in the ligation conditions described above.

The ligated mixture of DNA is used to transform competent CaCl₂ treated cells of E. coli K12 strain MM294. Transformants are selected on solid agar medium containing ampicillin (200 μg/ml).

One of the so-isolated colonies was shown to contain a plasmid, pRIT10812, consisting of the major pBR327 ClaI-BamHI fragment with an insert of the ClaIBglII fragment purified from pRIT10810. The plasmid was characterized in having the restriction map shown in FIG. 3.

EXAMPLE 13 Combination of the ctxA and ctxB fragment--Construction of pRIT10814

A 51 μg aliquot of purified plasmid DNA of pRIT10841 prepared as described in Example 11 is digested with 27 units of ClaI endonuclease for 18 hours at 37°. The mixture is electrophoresed on a 1% agarose gel and a gel slice containing the 1.0×10⁶ daltons ClaI DNA fragment excised.

The DNA is recovered from the gel slice by electroelution and ethanol precipitation.

A 2.86 μg aliquot of purified DNA of pRIT10812 prepared as described in Example 12 is digested with 11 units of ClaI endonuclease for 2 hours at 37° and treated with 0.25 units of calf intestine alkaline phosphatase as described in Example 7. The treated DNA is phenol extracted and ethanol precipitated. A 0.4 μg aliquot of this DNA is ligated with 0.5 μg of the purified ClaI DNA fragment isolated from pRIT 10841 in the ligation conditions described in Example 7 above. Half the ligated DNA mixture is used to transform competent CaCl₂ treated cells of E. coli K12 strain MM 294 with selection being made on solid agar medium with ampicilin (200 μg/ml). Plasmid DNA is prepared by the method of BIRNBOIM and DOLY (loc. cit.) from 12 colonies and restricted sequentially with PstI and XbaI endonucleases. One so-obtained plasmid gave a restriction fragment pattern indicative of insertion of the 1.0×10⁶ daltons ClaI fragment on pRIT10812 in the desired orientation and was further characterized.

Plasmid DNA was prepared from the clone by CsClethidium bromide centrifugation.

The plasmid DNA of clone MM294 (pRIT10814) was shown by restriction endonuclease analysis to have the structure shown in FIG. 3. A culture of MM294 (pRIT10814) has been deposited with the American Type Culture Collection under the accession number ATCC 39052.

The above combination steps are schematized in FIG. 3.

The orientation of the 1.0×10⁶ daltons ClaI DNA fragment from pRIT10841 on the recombinant plasmid pRIT10814 is deduced to be such as to juxtapose the ctxA sequence with the ctxB sequence at the ClaI site, i.e. to reform the complete cistrons specifying the structural gene for cholera toxin.

EXAMPLE 14 In vivo activity of ATCC 39052 strain

One ml samples of extracts of broth grown cells of ATCC 39052 strain prepared as described in Example 9 and containing 10 to 13 mg/ml total protein were injected into ligated intestinal loops of ten adult rabbits. The loops were examined 18 hours later and the fluid accumulation measured in each loop.

Considering that a ratio ≦0.5 means negative response and ≧0.5 means positive response, it appears from Table I that the extracts from ATCC 39052 strain gave a positive response in nine of ten animals.

In contrast, extracts of strain MM294 (pBR322) gave no measurable fluid accumulation in five animals tested. Injection of 100 ng purified cholera toxin per loop produced a positive response in eight of eight rabbits as did 10 ng purified toxin in three of eight rabbits. Extracts of ATCC 39051 strain (pRIT10810) and ATCC 39053 strain (pRIT10841) were also negative in tests on four and five rabbits respectively. This result shows that extracts of ATCC 39052 strain (pRIT10814) contain a substance capable of provoking an accumulation of fluid in the rabbit intestine as does cholera toxin. The ctxA and ctxB cistrons on pRIT10814 must therefore have been correctly religated at their common ClaI site so as to restore a functional structural gene specifying the synthesis of cholera holotoxin.

The results are given in Table I.

                  TABLE I                                                          ______________________________________                                         Adult rabbit intestinal loop test.                                                                             Average ratio:                                            No of     No giving  fluid volume                                              rabbits   positive   per cm intes-                                  Extract    tested    response   tinal loop                                     ______________________________________                                         Strain MM294                                                                              5         0          <0.1                                           (pBR322)                                                                       ATCC 39052 10        9          1.40                                           ATCC 39051 4         0          <0.1                                           ATCC 39053 5         0          <0.1                                           Cholera toxin                                                                  100 ng/ml  8         8          1.62                                            10 ng/ml  8         3          0.66                                           ______________________________________                                    

EXAMPLE 15 Cloning of a PstI DNA fragment containing both ctxA and ctxB cistrons from V. cholerae ATCC 39050

To verify the completeness of the cloned ClaI DNA fragments encoding the ctxA and ctxB cistrons a DNA fragment encompassing both cistrons was directly cloned from strain ATCC 39050. Analysis of total ATCC 39050 DNA digested with PstI endonuclease with the eltA and eltB probes using the methods and procedures described above in Examples 1 to 5 showed that both the ctxA and ctxB cistrons were present on a DNA fragment or fragments with a calculated molecular weight of 5.3×10⁶ d.

This fragment was enriched from a digest of 50 μg ATCC 39050 DNA with 100 units of PstI endonuclease by the methods and procedures described in Example 6 and an aliquot of 6 μl of the fraction showing the strongest hybridization response with the ClaI-HindII ctxB probe of V. cholerae DNA described in Example 9 was ligated to 0.4 μg of pBR322 plasmid DNA previously digested with PstI. This ligated DNA mixture was transformed into E. coli K12 strain MM294 with transformant colonies being selected on solid agar medium supplemented with 15 μg/ml tetracycline.

These colonies (about 14000 total) were transferred to Whatman 541 filter papers, the filters processed as described in Example 8 and hybridized with the radioactive ctxA fragment probe described in Example 11.

Eleven colonies were detected which showed a positive hybridization response to the ctxA probe and which were tetracycline resistant and ampicillin sensitive indicative of insertion of a foreign DNA fragment at the PstI site of the pBR322 vector. Plasmid DNA was prepared from one of these clones, strain MM294-(pRIT10824) and subjected to restriction enzyme analysis. The pRIT10824 plasmid contains a 5.1×10⁶ d insert at the Pstl site of the vector and digestion with ClaI endonuclease releases 5 fragments of which one corresponds in size to the 1.0×10⁶ d ctxB fragment previously cloned in pRIT10810 and one to the 2.45×10⁶ d ctxA fragment previously cloned in pRIT10841. In addition these 1.0×10⁶ d and 2.45×10⁶ d ClaI fragments from pRIT10824 possessed the same number and location of restriction sites as did the separately cloned fragments in pRIT10810 and pRIT10841. Furthermore comparison of restriction enzyme digests between pRIT10824 and pRIT10814 described in Example 13 showed no difference in the number of restriction fragments for enzymes or combinations of enzymes cutting in or around the ctx cistrons. A restriction map of pRIT10824 is shown in FIG. 4.

EXAMPLE 16 DNA sequences of the ctxA and ctx B cistrons

The nucleotide sequence of the DNA corresponding to the ctxA and ctxB cistrons was determined by the chemical modification method of MAXAM and GILBERT using the procedures described in Methods in Enzymology, 65, 499-560, 1980. Purified restriction fragments were labelled with ³² p at their 5' end either by exchange kination or by direct kination of dephosphorylated ends. Alternatively, 3' ends were labelled using terminal transferase and α-³² p-cordycepin (C.P. TU and S.N. COHEN, Gene, 10, 177-183, 1980). Fragments labelled at only one end were obtained by cleavage with a further restriction endonuclease and purification on polyacrylamide gel. The dimethylsulfate, hydrazine and sodium hydroxide reactions were used respectively for cleavage at guanine, pyrimidine and adenine. After piperidine cleavage the products were separated on thin 8% or 20% polyacrylamide gels (SANGER & COULSON, FEBS lett. 87, 107, 1978). The sequence was then read from the autoradiogram of the gel.

To ensure the greatest degree of precision in the sequence determination, overlapping DNA sequences were read from different labelled ends and both strands of the DNA sequenced wherever possible. The recombinant plasmids, the restriction sites chosen for labelling and the extent of sequence read in each determination are shown in FIG. 5.

The DNA sequence derived by these methods is shown in FIG. 6 and comprises 1148 nucleotides of which nucleotides 1 to 777 inclusive form the coding sequence for the A subunit and nucleotides 774 to 1148 inclusive form the coding sequence for the B subunit. It is important that in the present sequence there exist extensive regions which correspond to known amino acid sequences for the A subunit and B subunit proteins of E. coli heat labile enterotoxin (see SPICER E. and coll.: Proc. Natl. Acad. Sci. US 78, 50, 1981) always excepting errors and omission in such protein sequence determinations. It is also to be realised that variations in codons and amino acids may exist between different strains of Vibrio cholerae for both the A and B subunits and that the present invention is not limited to the sequence described above but includes all functional equivalents of the above described sequence. This is exemplified by comparison of the B subunit protein sequence for the present El Tor Vibrio strain and the known amino acid sequence determined by LAI (J. Biol. Chem. 252, 7249, 1977) for the B protein of the classical Vibrio strain 569B (ATCC 25870) where five amino acid differences exist, notably at positions 18, 22, 47, 54 and 70, in the mature amino acid sequence.

It is also to be noted that the coding sequence of the A subunit protein runs through the ClaI site marking the end of the ctxA gene fragment extending into and terminating at nucleotide 777 within the so called ctxB gene fragment.

EXAMPLE 17 Vaccine preparation

E. coli ATCC 39051 strain is allowed to grow in syncase medium (loc. cit.) to reach stationary phase. The culture is then centrifuged and filtered and the resulting filtrate is concentrated, dialyzed and adsorbed with aluminium hydroxide. After washing, the solution of subunit B of cholera toxin is eluted with 0.1 M sodium citrate, buffered at pH 7.2 with phosphate buffer, distributed into 2 ml vials containing 200 antitoxin units per ml and freeze-dried.

Freshly rehydrated vials are used for oral administration, the vaccination schedule comprising a booster administration 30 days after the first one, each administration being preceded by oral administration of 2 g of sodium bicarbonate in 60 ml of water. 

We claim:
 1. A recombinant DNA molecule comprising at least a portion coding for subunits A and B of cholera toxin, or a fragment or derivative of said portion wherein the fragment or derivative codes for a polypeptide having an activity which (a) can induce an immune response to subunit A; (b) can induce an immune response to subunit A and cause epithelial cell penetration and the enzymatic effect leading to net loss of fluid into the gut lumen; (c) can bind to the membrane receptor for the B subunit of cholera toxin; (d) can induce an immune response to subunit B; (e) can induce an immune response to subunit B and bind to said membrane receptor; or (f) has a combination of said activities.
 2. A DNA sequence of the formula:

    __________________________________________________________________________     5'-                                                                            10       20       30       40       50                                         ATGGTAAAGA                                                                              TAATATTTGT                                                                              GTTTTTTATT                                                                              TTCTTATCAT                                                                              CATTTTCATA                                 60       70       80       90       100                                        TGCAAATGAT                                                                              GATAAGTTAT                                                                              ATCGGGCAGA                                                                              TTCTAGACCT                                                                              CCTGATGAAA                                 110      120      130      140      150                                        TAAAGCAGTC                                                                              AGGTGGTCTT                                                                              ATGCCAAGAG                                                                              GACAGAGTGA                                                                              GTACTTTGAC                                 160      170      180      190      200                                        CGAGGTACTC                                                                              AAATGAATAT                                                                              CAACCTTTAT                                                                              GATCATGCAA                                                                              GAGGAACTCA                                 210      220      230      240      250                                        GACGGGATTT                                                                              GTTAGGCACG                                                                              ATGATGGATA                                                                              TGTTTCCACC                                                                              TCAATTAGTT                                 260      270      280      290      300                                        TGAGAAGTGC                                                                              CCACTTAGTG                                                                              GGTCAAACTA                                                                              TATTGTCTGG                                                                              TCATTCTACT                                 310      320      330      340      350                                        TATTATATAT                                                                              ATGTTATAGC                                                                              CACTGCACCC                                                                              AACATGTTTA                                                                              ACGTTAATGA                                 360      370      380      390      400                                        TGTATTAGGG                                                                              GCATACAGTC                                                                              CTCATCCAGA                                                                              TGAACAAGAA                                                                              GTTTCTGCTT                                 410      420      430      440      450                                        TAGGTGGGAT                                                                              TCCATACTCC                                                                              CAAATATATG                                                                              GATGGTATCG                                                                              AGTTCATTTT                                 460      470      480      490      500                                        GGGGTGCTTG                                                                              ATGAACAATT                                                                              ACATCGTAAT                                                                              AGGGGCTACA                                                                              GAGATAGATA                                 510      520      530      540      550                                        TTACAGTAAC                                                                              TTAGATATTG                                                                              CTCCAGCAGC                                                                              AGATGGTTAT                                                                              GGATTGGCAG                                 560      570      580      590      600                                        GTTTCCCTCC                                                                              GGAGCATAGA                                                                              GCTTGGAGGG                                                                              AAGAGCCGTG                                                                              GATTCATCAT                                 610      620      630      640      650                                        GCACCGCCGG                                                                              GTTGTGGGAA                                                                              TGCTCCAAGA                                                                              TCATCGATGA                                                                              GTAATACTTG                                 660      670      680      690      700                                        CGATGAAAAA                                                                              ACCCAAAGTC                                                                              TAGGTGTAAA                                                                              ATTCCTTGAC                                                                              GAATACCAAT                                 710      720      730      740      750                                        CTAAAGTTAA                                                                              AAGACAAATA                                                                              TTTTCAGGCT                                                                              ATCAATCTGA                                                                              TATTGATACA                                 760      770      780      790      800                                        CATAATAGAA                                                                              TTAAGGATGA                                                                              ATTATGATTA                                                                              AATTAAAATT                                                                              TGGTGTTTTT                                 810      820      830      840      840                                        TTTACAGTTT                                                                              TACTATCTTC                                                                              AGCATATGCA                                                                              CATGGAACAC                                                                              CTCAAAATAT                                 860      870      880      890      900                                        TACTGATTTG                                                                              TGTGCAGAAT                                                                              ACCACAACAC                                                                              ACAAATATAT                                                                              ACGCTAAATG                                 910      920      930      940      950                                        ATAAGATATT                                                                              TTCGTATACA                                                                              GAATCTCTAG                                                                              CTGGAAAAAG                                                                              AGAGATGGCT                                 960      970      980      990      1000                                       ATCATTACTT                                                                              TTAAGAATGG                                                                              TGCAATTTTT                                                                              CAAGTAGAAG                                                                              TACCAAGTAG                                 1010     1020     1030     1040     1050                                       TCAACATATA                                                                              GATTCACAAA                                                                              AAAAAGCGAT                                                                              TGAAAGGATG                                                                              AAGGATACCC                                 1060     1070     1080     1090     1100                                       TGAGGATTGC                                                                              ATATCTTACT                                                                              GAAGCTAAAG                                                                              TCGAAAAGTT                                                                              ATGTGTATGG                                 1110     1120     1130     1140     1150                                       AATAATAAAA                                                                              CGCCTCATGC                                                                              GATTGCCGCA                                                                              ATTAGTATGG                                                                              CAAATTAA                                   3'                                                                             __________________________________________________________________________

and fragments and derivatives thereof, said fragments and derivatives coding for subunits A and B of cholera toxin or for a polypeptide having an activity which (a) can induce an immune response to subunit A; (b) can induce an immune response to subunit A and cause epithelial cell penetration and the enzymatic effect leading to net loss of fluid into the gut lumen; (c) can bind to the membrane receptor for the B subunit of cholera toxin; (d) can induce an immune response to subunit B; (e) can induce an immune response to subunit B and bind to said membrane receptor; or (f) has a combination of said activities.
 3. A recombinant DNA molecule according to claim 1 wherein the portion coding for said subunits A and B of cholera toxin or the fragment or derivative of said portion is operatively linked to an expression control sequence.
 4. The recombinant DNA molecule pRIT18014.
 5. A host microorganism transformed with at least one recombinant DNA molecule according to claim
 3. 6. The E. coli ATCC 39052 strain.
 7. A recombinant DNA molecule according to claim 1 comprising at least a portion coding for subunit A of cholera toxin, or a fragment or derivative of said portion wherein the fragment or derivative codes for a polypeptide which can induce an immune response to subunit A of cholera toxin or which can induce an immune response to subunit A and cause epithelial cell penetration and the enzymatic effect leading to net loss of fluid into the gut lumen.
 8. A fragment of the DNA sequence according to claim 2 of the formula:

    __________________________________________________________________________     5'-                                                                            10       20       30       40       50                                         ATGGTAAAGA                                                                              TAATATTTGT                                                                              GTTTTTATT                                                                               TTCTTATCAT                                                                              CATTTTCATA                                 60       70       80       90       100                                        TGCAAATGAT                                                                              GATAAGTTAT                                                                              ATCGGGCAGA                                                                              TTCTAGACCT                                                                              CCTGATGAAA                                 110      120      130      140      150                                        TAAAGCAGTC                                                                              AGGTGGTCTT                                                                              ATGCCAAGAG                                                                              GACAGAGTGA                                                                              GTACTTTGAC                                 160      170      180      190      200                                        CGAGGTACTC                                                                              AAATGAATAT                                                                              CAACCTTTAT                                                                              GATCATGCAA                                                                              GAGGAACTCA                                 210      220      230      240      250                                        GACGGGATTT                                                                              GTTAGGCACG                                                                              ATGATGGATA                                                                              TGTTTCCACC                                                                              TCAATTAGTT                                 260      270      280      290      300                                        TGAGAAGTGC                                                                              CCACTTAGTG                                                                              GGTCAAACTA                                                                              TATTGTCTGG                                                                              TCATTCTACT                                 310      320      330      340      350                                        TATTATATAT                                                                              ATGTTATAGC                                                                              CACTGCACCC                                                                              AACATGTTTA                                                                              ACGTTAATGA                                 360      370      380      390      400                                        TGTATTAGGG                                                                              GCATACAGTC                                                                              CTCATCCAGA                                                                              TGAACAAGAA                                                                              GTTTCTGCTT                                 410      420      430      440      450                                        TAGGTGGGAT                                                                              TCCATACTCC                                                                              CAAATATATG                                                                              GATGGTATCG                                                                              AGTTCATTTT                                 460      470      480      490      500                                        GGGGTGCTTG                                                                              ATGAACAATT                                                                              ACATCGTAAT                                                                              AGGGGCTACA                                                                              GAGATAGATA                                 510      520      530      540      550                                        TTACAGTAAC                                                                              TTAGATATTG                                                                              CTCCAGCAGC                                                                              AGATGGTTAT                                                                              GGATTGGCAG                                 560      570      580      590      600                                        GTTTCCCTCC                                                                              GGAGCATAGA                                                                              GCTTGGAGGG                                                                              AAGAGCCGTG                                                                              GATTCATCAT                                 610      620      630      640      650                                        GCACCGCCGG                                                                              GTTGTGGGAA                                                                              TGCTCCAAGA                                                                              TCATCGATCA                                                                              GTAATACTTG                                 660      670      680      690      700                                        CGATGAAAAA                                                                              ACCCAAAGTC                                                                              TAGGTGTAAA                                                                              ATTCCTTGAC                                                                              GAATACCAAT                                 710      720      730      740      750                                        CTAAAGTTAA                                                                              AAGACAAATA                                                                              TTTTCAGGCT                                                                              ATCAATCTGA                                                                              TATTGATACA                                 760      770      780      790      800                                        CATAATAGAA                                                                              TTAAGGATGA                                                                              ATTATGA                                                      3'                                                                             __________________________________________________________________________

and fragments and derivatives thereof, said fragments and derivatives coding for subunit A of cholera toxin or for a polypeptide which can induce an immune response to subunit A of cholera toxin or which can induce an immune response to subunit A and cause epithelial cell penetration and the enzymatic effect leading to net loss of fluid into the gut lumen.
 9. A recombinant DNA molecule according to claim 7 wherein the portion coding for said subunit A of cholera toxin or the fragment or derivative of said portion is operatively linked to an expression control sequence.
 10. The recombinant DNA molecule pRIT10841.
 11. A host microorganism transformed with at least one recombinant DNA molecule according to claim
 9. 12. The E. coli ATCC 39053 strain.
 13. A recombinant DNA molecule according to claim 1 comprising at least a portion coding for subunit B of cholera toxin, or a fragment or derivative of said portion wherein the fragment or derivative codes for a polypeptide which can induce an immune response to subunit B of cholera toxin or which can bind to the membrane receptor for subunit B of cholera toxin or which can both induce such immune response and bind to said membrane receptor.
 14. A fragment of the DNA sequence according to claim 2 of the formula:

    __________________________________________________________________________     5'-                                                                                              780      790      800                                                          ATGATTA  AATTAAAATT                                                                              TGGTGTTTTT                                 810      820      830      840      840                                        TTTACAGTTT                                                                              TACTATCTTC                                                                              AGCATATGCA                                                                              CATGGAACAC                                                                              CTCAAAATAT                                 860      870      880      890      900                                        TACTGATTTG                                                                              TGTGCAGAAT                                                                              ACCACAACAC                                                                              ACAAATATAT                                                                              ACGCTAAATG                                 910      920      930      940      950                                        ATAAGATATT                                                                              TTCGTATACA                                                                              GAATCTCTAG                                                                              CTGGAAAAAG                                                                              AGAGATGGCT                                 960      970      980      990      1000                                       ATCATTACTT                                                                              TTAAGAATGG                                                                              TGCAATTTTT                                                                              CAAGTAGAAG                                                                              TACCAAGTAG                                 1010     1020     1030     1040     1050                                       TCAACATATA                                                                              GATTCACAAA                                                                              AAAAAGCGAT                                                                              TGAAAGGATG                                                                              AAGGATACCC                                 1060     1070     1080     1090     1100                                       TGAGGATTGC                                                                              ATATCTTACT                                                                              GAAGCTAAAG                                                                              TGAAAAGTT                                                                               ATGTGTATGG                                 1110     1120     1130     1140     1150                                       AATAATAAAA                                                                              CGCCTCATGC                                                                              GATTGCCGCA                                                                              ATTAGTATGG                                                                              CAAATTAA                                   3'                                                                             __________________________________________________________________________

and fragments and derivatives thereof, said fragments and derivatives coding for subunit B of cholera toxin or for a polypeptide which can induce an immune response to subunit B of cholera toxin or which can bind to the membrane receptor for subunit B of cholera toxin or which can both induce such immune response and bind to said membrane receptor.
 15. A recombinant DNA molecule according to claim 13 wherein the portion coding for said subunit B of cholera toxin or the fragment or derivative of said portion is operatively linked to an expression control sequence.
 16. The recombinant DNA molecule pRIT10810.
 17. A host microorganism transformed with at least one recombinant DNA molecule according to claim
 15. 18. The process for preparing a recombinant DNA molecule selected from the group consisting of a recombinant DNA molecule comprising at least a portion coding for subunit A of cholera toxin or a fragment or derivative of said portion wherein the fragment or derivative codes for a polypeptide which can induce an immune response to subunit A of cholera toxin or which can induce an immune response to subunit A and cause epithelial cell penetration and the enzymatic effect leading to net loss of fluid into the gut lumen and the recombinant DNA molecule pRIT10841, comprising digesting DNA of a V. cholerae strain producing subunit A of the cholera toxin with Cla I endonuclease; isolating a fragment having specific hybridization to an eltA probe; mixing said fragment with a vector having a Cla I endonuclease restriction site and previously Cla I digested; and inserting the fragment into said vector.
 19. A process for producing subunit A of cholera toxin comprising providing a recombinant DNA molecule, said recombinant DNA molecule comprising the sequence coding for subunit A of cholera toxin; inserting said recombinant DNA molecule at a Cla I endonuclease restriction site of an appropriate vector to produce a hybrid vector; transforming an appropriate host with said hybrid vector; culturing the transformed host; allowing the transformed host to synthesize subunit A of cholera toxin; and collecting said subunit A of cholera toxin.
 20. A process according to claim 19 wherein the appropriate vector is plasmid pBR322.
 21. The process for preparing a recombinant DNA molecule selected from the group consisting of a recombinant DNA molecule comprising at least a portion coding for subunit B of cholera toxin, or a fragment or derivative of said portion wherein the fragment or derivative codes for a polypeptide which can induce an immune response to subunit B of cholera toxin or which can bind to the membrane receptor for subunit B of cholera toxin or which can both induce such immune response and bind to said membrane receptor and the recombinant DNA moledule pRIT10810, comprising digesting DNA of a V. cholerae strain producing subunit B of the cholera toxin with Cla I endonuclease; isolating a fragment showing specific hybridization to an eltB probe; mixing said fragment with a vector having a Cla I endonuclease restriction site and previously Cla I digested; and inserting the fragment into said vector.
 22. A process for producing subunit B of cholera toxin comprising providing a recombinant DNA molecule, said recombinant DNA molecule comprising the sequence coding for subunit B of cholera toxin; inserting said recombinant DNA molecule at a Cla I endonuclease restriction site of an appropriate vector to produce a hybrid vector; transforming an appropriate host with said hybrid vector; culturing the transformed host; allowing the transformed host to synthesize subunit B of cholera toxin; and collecting said subunit B of cholera toxin.
 23. The process for preparing a recombinant DNA molecule selected from the group consisting of a recombinant DNA molecule comprising at least a portion coding for subunits A and B of cholera toxin, or a fragment or derivative of said portion wherein the fragment or derivative codes for a polypeptide having an activity which (a) can induce an immune response to subunit A; (b) can induce an immune response to subunit A and cause epithelial cell penetration and the enzymatic effect leading to net loss of fluid into the gut lumen; (c) can bind to the membrane receptor for the B subunit of cholera toxin; (d) can induce an immune response to subunit B; (e) can induce an immune response to subunit B and bind to said membrane receptor; or (f) has a combination of said activities and the recombinant DNA molecule pRIT10814, comprising digesting a DNA sequence encoding subunit B of the cholera toxin sequentially with Cla I and an endonuclease not cutting the sequence coding for B subunit; isolating the resulting fragment; inserting said fragment into an adequate vector which has been sequentially digested with Cla I endonuclease and a second appropriate endonuclease to yield a recombinant DNA molecule which recombinant DNA molecule is then either (g) digested with Cla I endonuclease or (h) digested sequentially with Cla I endonuclease and a second endonulcease and wherein the DNA fragment resulting from (g) or (h) is combined with a DNA fragment obtained by digesting DNA from a V. cholerae strain producing subunit A of the cholera toxin with either (i) Cla I endonuclease or (j) Cla I endonuclease and sequentially a second endonuclease.
 24. A process for producing subunits A and B of cholera toxin comprising providing a recombinant DNA molecule, said recombinant DNA molecule comprising the sequence coding for subunit A of cholera toxin and the sequence coding for subunit B of cholera toxin; inserting said recombinant DNA coding for subunit A and subunit B of cholera toxin and the expression control sequence for said recombinant DNA coding for subunit A of cholera toxin at a Cla I endonuclease restriction site of an appropriate vector to produce a hybrid vector; transforming an appropriate host with said hybrid vector; culturing the transformed host; allowing the transformed host to synthesize subunits A and B of cholera toxin; and collecting said subunits A and B of cholera toxin.
 25. A process according to claim 24 wherein the hybrid vector is plasmid pRIT10812.
 26. The E. coli ATCC 39051 strain. 